Detection of Eccentricity Faults in Five-Phase Ferrite-PM Assisted Synchronous Reluctance Machines

: Air gap eccentricity faults in ﬁve-phase ferrite-assisted synchronous reluctance motors (fPMa-SynRMs) tend to distort the magnetic ﬂux in the air gap, which in turn affects the spectral content of both the stator currents and the ZSVC (zero-sequence voltage component). However, there is a lack of research dealing with the topic of fault diagnosis in multi-phase PMa-SynRMs, and in particular, those focused on detecting eccentricity faults. An analysis of the spectral components of the line currents and the ZSVC allows the development of fault diagnosis algorithms to detect eccentricity faults. The effect of the operating conditions is also analyzed, since this paper shows that it has a non-negligible impact on the effectivity and sensitivity of the diagnosis based on an analysis of the stator currents and the ZSVC. To this end, different operating conditions are analyzed. The paper also evaluates the inﬂuence of the operating conditions on the harmonic content of the line currents and the ZSVC, and determines the most suitable operating conditions to enhance the sensitivity of the analyzed methods. Finally, fault indicators employed to detect eccentricity faults, which are based on the spectral content of the stator currents and the ZSVC, are derived and their performance is assessed. The approach presented in this work may be useful for developing fault diagnosis strategies based on the acquisition and subsequent analysis and interpretation of the spectral content of the line currents and the ZSVC. to measure the ZSVC using a ﬁve-phase balanced resistor network to generate the artiﬁcial neutral point.


Introduction
In recent years, SynRMs (synchronous reluctance machines) have become popular because of the volatility of the rare-earth PM (permanent magnet) price, concerns about the risk of supply [1], or the demand of highly-efficient machines. These factors are promoting SynRMs and ferrite-PM assisted SynRMs (fPMa-SynRMs) to be competitors of induction machines [2] and PM synchronous machines [3] in many applications requiring a high efficiency and torque density, wide constant-power speed range or overload capability [4]. Ferrite-assisted SynRMs rely on abundant and low-cost ferrite PMs, offering a good option since they generate both magnetic and reluctance torques [5]. PMa-SynRMs offer a lower cost and higher reluctance torque than IPM (interior-PM) motors, since PMa-SynRMs require a smaller volume of magnets because the reluctance torque is the main component of the total torque. Due to the reluctance torque, SynRMs present a higher torque ripple compared to other motors; however, by applying selected rotor steps, rotor skewing, or asymmetric flux barriers, the pulsation of the torque can be reduced [2]. been applied to analyze the different machines, since FEM is a recognized simulation method that allows an accurate electromagnetic analysis [26] and assists in the optimal design process of electrical machines [27]. FEM also allows one to compute the values of key machine variables, and thus, permits an analysis of the behavior of suitable parameters to be used in fault detection approaches to characterize the motor failures under analysis [20].
The detection of failures in PMaSynRMs is a hot topic due to the growing interest of these machines for vehicular traction applications. The particular geometry of such motors hinders the on-line detection of eccentricity faults. This paper proves that when selecting favorable operating points, the detection is possible. This paper also proposes an on-line eccentricity fault detection approach, which includes the calculation of fault indicators from the spectral content of the stator currents and the ZSVC. The calculation process of such indicators presents a low computational burden, which is a requisite for on-line applications.

The Analyzed Machine
This paper deals with a PMa-SynRm, whose main features are summarized in Table 1. The analyzed motor has a fault-tolerant winding, since each slot only accommodates a unique phase, as shown in Figure 1. In addition, the combination of the low current design and the large inductances (each slot includes 60 conductors) reduces the risk of high short-circuit currents.
Appl. Sci. 2017, 7, 565 3 of 14 thus, permits an analysis of the behavior of suitable parameters to be used in fault detection approaches to characterize the motor failures under analysis [20]. The detection of failures in PMaSynRMs is a hot topic due to the growing interest of these machines for vehicular traction applications. The particular geometry of such motors hinders the on-line detection of eccentricity faults. This paper proves that when selecting favorable operating points, the detection is possible. This paper also proposes an on-line eccentricity fault detection approach, which includes the calculation of fault indicators from the spectral content of the stator currents and the ZSVC. The calculation process of such indicators presents a low computational burden, which is a requisite for on-line applications.

The Analyzed Machine
This paper deals with a PMa-SynRm, whose main features are summarized in Table 1. The analyzed motor has a fault-tolerant winding, since each slot only accommodates a unique phase, as shown in Figure 1. In addition, the combination of the low current design and the large inductances (each slot includes 60 conductors) reduces the risk of high short-circuit currents. The results presented in this paper are based on a healthy and a faulty machine with a static eccentricity of 40% of the air gap length. It is noted that although this paper analyzes the effects of static eccentricity faults, dynamic eccentricity produces comparable results, and thus similar conclusions apply for both eccentricity types.
The d axis is taken as the direction of maximum magnetic flux in the rotor, which is the direction of the magnetic flux in the rotor following the magnetic path. The minimum flux corresponds to the q axis, corresponding to the direction of the magnetic flux crossing the air barriers, as shown in Figure 2. It is noted that the currents in the dq reference frame (id,iq) can be calculated from the line currents (ia, ib, ic, id, ie) as: The results presented in this paper are based on a healthy and a faulty machine with a static eccentricity of 40% of the air gap length. It is noted that although this paper analyzes the effects of static eccentricity faults, dynamic eccentricity produces comparable results, and thus similar conclusions apply for both eccentricity types.
The d axis is taken as the direction of maximum magnetic flux in the rotor, which is the direction of the magnetic flux in the rotor following the magnetic path. The minimum flux corresponds to the q axis, corresponding to the direction of the magnetic flux crossing the air barriers, as shown in Figure 2. The results presented in this paper are based on a healthy and a faulty machine with a static eccentricity of 40% of the air gap length. It is noted that although this paper analyzes the effects of static eccentricity faults, dynamic eccentricity produces comparable results, and thus similar conclusions apply for both eccentricity types.
The d axis is taken as the direction of maximum magnetic flux in the rotor, which is the direction of the magnetic flux in the rotor following the magnetic path. The minimum flux corresponds to the q axis, corresponding to the direction of the magnetic flux crossing the air barriers, as shown in Figure 2. It is noted that the currents in the dq reference frame (id,iq) can be calculated from the line currents (ia, ib, ic, id, ie) as: π θ π θ π θ π θ θ π θ π θ π θ π θ θ (1) and the current angle is calculated as:  It is noted that the currents in the dq reference frame (i d ,i q ) can be calculated from the line currents (i a , i b , i c , i d , i e ) as: and the current angle is calculated as:  The permanent magnets in the rotor are placed in the negative direction of the q axis, so when the motor is positioned in the d axis, the net flux through the stator windings due to the permanent magnets is null. This is illustrated in Figure 3a, which shows one pole of a five-phase machine positioned in the d axis when neglecting the effects of the stator currents. The total flux through the windings is null since the flux in phase A is also null due to the arrangement shown in Figure 3a, whereas phases B and E, and C and D, are complementary, so the net flux is zero.
It is known that the winding configuration in rotating field machines greatly impacts the power capability and the spectral content of both the mmf and back-emf. These effects are reflected in the harmonic composition of the line currents and the ZSVC [21].

Detection of Air Gap Eccentricity Faults in PMa-SynRM from the Stator Currents Spectrum
The research dealing with a three-phase SynRM found in [18] and [28] shows that static eccentricity faults induce triplen harmonic frequencies in the stator currents, although it is known that supply unbalance may also induce such harmonic components, thus hindering the interpretation. These works also conclude that dynamic eccentricity does not generate new harmonic components in the stator currents, although it modifies the odd harmonics. Static eccentricity induces harmonic components in the stator current harmonics which can be localized as [9,10,[29][30][31]: where p is the number of pole pairs of the motor and fs is the supply frequency. Therefore, from (3), it is deduced that eccentricity faults can induce particular fractional harmonic frequencies in the stator currents spectra that can be used for diagnosis purposes. The set of harmonics predicted by (3) is present under both stationary and nonstationary operating conditions.
The line currents are already measured by the current probes included in the drive supplying the PMa-SynRM. Therefore, no additional sensors are necessary. Since, as explained, the amplitude of the stator currents harmonics may be altered by the current loops of the electronic drive, it can hinder the diagnosis from the study of the stator currents. Therefore, the ZSVC-based method is also applied in this work. The permanent magnets in the rotor are placed in the negative direction of the q axis, so when the motor is positioned in the d axis, the net flux through the stator windings due to the permanent magnets is null. This is illustrated in Figure 3a, which shows one pole of a five-phase machine positioned in the d axis when neglecting the effects of the stator currents. The total flux through the windings is null since the flux in phase A is also null due to the arrangement shown in Figure 3a, whereas phases B and E, and C and D, are complementary, so the net flux is zero.
It is known that the winding configuration in rotating field machines greatly impacts the power capability and the spectral content of both the mmf and back-emf. These effects are reflected in the harmonic composition of the line currents and the ZSVC [21].

Detection of Air Gap Eccentricity Faults in PMa-SynRM from the Stator Currents Spectrum
The research dealing with a three-phase SynRM found in [18] and [28] shows that static eccentricity faults induce triplen harmonic frequencies in the stator currents, although it is known that supply unbalance may also induce such harmonic components, thus hindering the interpretation. These works also conclude that dynamic eccentricity does not generate new harmonic components in the stator currents, although it modifies the odd harmonics. Static eccentricity induces harmonic components in the stator current harmonics which can be localized as [9,10,[29][30][31]: where p is the number of pole pairs of the motor and f s is the supply frequency. Therefore, from (3), it is deduced that eccentricity faults can induce particular fractional harmonic frequencies in the stator currents spectra that can be used for diagnosis purposes. The set of harmonics predicted by (3) is present under both stationary and nonstationary operating conditions. The line currents are already measured by the current probes included in the drive supplying the PMa-SynRM. Therefore, no additional sensors are necessary. Since, as explained, the amplitude of the stator currents harmonics may be altered by the current loops of the electronic drive, it can hinder the diagnosis from the study of the stator currents. Therefore, the ZSVC-based method is also applied in this work.

Detection of Air Gap Eccentricity Faults in PMa-SynRM from the ZSVC Spectrum
To measure the ZSVC, the central point of the wye-connected stator windings must be accessible [21]. In addition, a balanced three-phase inexpensive resistor network is required to generate an artificial neutral point. This approach is compatible with fault tolerant drives adding an extra inverter branch to replace the failed phase, which is connected to the central point of the windings [32,33]. In this way, the ZSVC injected by the electronic drive can be removed from the neutral voltage of the PMa-SynRM [34].
When dealing with a symmetric and healthy machine, according the layout shown in Figure 4, the fundamental harmonic of the v 0,m zero-sequence voltage component measured between the artificial neutral point and the central point of the stator windings can be expressed as [34]: where λ PM,0 is the zero-sequence flux component produced by the permanent magnets.
In the case of a salient machine affected by an eccentricity fault, an additional term appears in (4) due to the changing air gap in the phase inductances.

Detection of Air Gap Eccentricity Faults in PMa-SynRM from the ZSVC Spectrum
To measure the ZSVC, the central point of the wye-connected stator windings must be accessible [21]. In addition, a balanced three-phase inexpensive resistor network is required to generate an artificial neutral point. This approach is compatible with fault tolerant drives adding an extra inverter branch to replace the failed phase, which is connected to the central point of the windings [32,33]. In this way, the ZSVC injected by the electronic drive can be removed from the neutral voltage of the PMa-SynRM [34].
When dealing with a symmetric and healthy machine, according the layout shown in Figure 4, the fundamental harmonic of the v0,m zero-sequence voltage component measured between the artificial neutral point and the central point of the stator windings can be expressed as [34]: where λPM,0 is the zero-sequence flux component produced by the permanent magnets.
In the case of a salient machine affected by an eccentricity fault, an additional term appears in (4) due to the changing air gap in the phase inductances.

Results
Both the stator currents spectra and the ZSVC spectra of the fPMa-SynRM described in Section 2 are analyzed when the machine operates under healthy and air gap eccentricity fault conditions. The results presented in this section are based on two-dimensional FEM models built and calculated by means of the FLUX ® 12.1 rotating machines software, whereas the post-processing analysis was developed with the Matlab-2015b ® software package. The two-dimensional mesh of the analyzed PMa-SynRM models comprises about 72,652 triangular elements. The supply frequency considered for simulation purposes was set to 500 Hz for all analyzed machines. A total of 60 electrical cycles were simulated with a sampling frequency of 120 kHz, thus obtaining a total of 7200 sample points, with 120 points in each electrical period.

Motor Working under Rated Operating Conditions
The first study focuses on the detection of eccentricity faults when the analyzed fPMa-SynRM operates under rated conditions, that is, 4 ARMS, 3.5 kW, 240 VRMS, 5000 rev/min, and 65° current angle (between d-0° and q-90° axes). Figure 5 shows the spectral content of the line currents of the analyzed fPMa-SynRM under healthy and 40% static eccentricity conditions.

Results
Both the stator currents spectra and the ZSVC spectra of the fPMa-SynRM described in Section 2 are analyzed when the machine operates under healthy and air gap eccentricity fault conditions. The results presented in this section are based on two-dimensional FEM models built and calculated by means of the FLUX ® 12.1 rotating machines software, whereas the post-processing analysis was developed with the Matlab-2015b ® software package. The two-dimensional mesh of the analyzed PMa-SynRM models comprises about 72,652 triangular elements. The supply frequency considered for simulation purposes was set to 500 Hz for all analyzed machines. A total of 60 electrical cycles were simulated with a sampling frequency of 120 kHz, thus obtaining a total of 7200 sample points, with 120 points in each electrical period.

Motor Working under Rated Operating Conditions
The first study focuses on the detection of eccentricity faults when the analyzed fPMa-SynRM operates under rated conditions, that is, 4 A RMS , 3.5 kW, 240 V RMS , 5000 rev/min, and 65 • current angle (between d-0 • and q-90 • axes). Figure 5 shows the spectral content of the line currents of the analyzed fPMa-SynRM under healthy and 40% static eccentricity conditions. The results presented in Figure 5 show minor differences between the spectral content of healthy and faulty machines, and it is thus difficult to detect eccentricity faults from the analysis of the line currents when the motor operates under rated conditions. The low discrimination attained between healthy and faulty conditions by the method based on the stator currents is attributed to the high reluctance path of the magnetic flux due to the combined effect of the saturation of the rotor segments placed between the flux barriers and the flux crossing the flux barriers. This reluctance takes similar values to those of the air gap, thus hindering the discrimination of the method based on the analysis of the stator currents spectra. Figure 6 shows the spectral content of the ZSVC of the analyzed fPMa-SynRM under healthy and 40% static eccentricity conditions. It is noted that both the stator currents and ZSVC spectra are normalized with respect to the maximum value of the respective waveform. The results presented in Figure 6 clearly show a better sensitivity of the ZSVC-based method compared to the method based on the analysis of the stator currents.
However, to attain a better discrimination, it is suggested that other operating conditions in which the machine and specifically, the rotor segments, work under less saturated conditions are analyzed.  The results presented in Figure 5 show minor differences between the spectral content of healthy and faulty machines, and it is thus difficult to detect eccentricity faults from the analysis of the line currents when the motor operates under rated conditions. The low discrimination attained between healthy and faulty conditions by the method based on the stator currents is attributed to the high reluctance path of the magnetic flux due to the combined effect of the saturation of the rotor segments placed between the flux barriers and the flux crossing the flux barriers. This reluctance takes similar values to those of the air gap, thus hindering the discrimination of the method based on the analysis of the stator currents spectra. Figure 6 shows the spectral content of the ZSVC of the analyzed fPMa-SynRM under healthy and 40% static eccentricity conditions.   It is noted that both the stator currents and ZSVC spectra are normalized with respect to the maximum value of the respective waveform. The results presented in Figure 6 clearly show a better sensitivity of the ZSVC-based method compared to the method based on the analysis of the stator currents.
However, to attain a better discrimination, it is suggested that other operating conditions in which the machine and specifically, the rotor segments, work under less saturated conditions are analyzed.

Motor Working under Low-Load (Low-Saturation) Conditions
The second study focuses on the detection of eccentricity faults when the analyzed fPMa-SynRM works under low-load conditions, and thus, less saturation. This study assumes that the operating conditions are 0.7 A RMS , 130 V RMS , 5000 rev/min, and 40 • current angle (between d-0 • and q-90 • ). It is noted that a low current means a low magnetic saturation of the rotor segments. Figure 7 shows the spectral content of the line currents of the analyzed fPMa-SynRM working under low-current and low-saturation conditions, for both healthy and 40% static eccentricity conditions. Appl. Sci. 2017, 7, 565 8 of 14

Motor Working under Low-Load (Low-Saturation) Conditions
The second study focuses on the detection of eccentricity faults when the analyzed fPMa-SynRM works under low-load conditions, and thus, less saturation. This study assumes that the operating conditions are 0.7 ARMS, 130 VRMS, 5000 rev/min, and 40° current angle (between d-0° and q-90°). It is noted that a low current means a low magnetic saturation of the rotor segments. Figure 7 shows the spectral content of the line currents of the analyzed fPMa-SynRM working under low-current and low-saturation conditions, for both healthy and 40% static eccentricity conditions.   As proved in Figures 7 and 8, the discrimination power decreases (both healthy and faulty spectra are almost superimposed) with respect to the operating point corresponding to the nominal conditions, since almost all of the magnetic flux flowing through the stator windings is due to the permanent magnets in the rotor, and thus, the reluctance of the path followed by the magnetic flux in the rotor is high compared to the reluctance of the air gap, thus hindering the detection of such faults.

Motor Working under Low-Load (Low-Saturation) Conditions
The second study focuses on the detection of eccentricity faults when the analyzed fPMa-SynRM works under low-load conditions, and thus, less saturation. This study assumes that the operating conditions are 0.7 ARMS, 130 VRMS, 5000 rev/min, and 40° current angle (between d-0° and q-90°). It is noted that a low current means a low magnetic saturation of the rotor segments. Figure 7 shows the spectral content of the line currents of the analyzed fPMa-SynRM working under low-current and low-saturation conditions, for both healthy and 40% static eccentricity conditions.   As proved in Figures 7 and 8, the discrimination power decreases (both healthy and faulty spectra are almost superimposed) with respect to the operating point corresponding to the nominal conditions, since almost all of the magnetic flux flowing through the stator windings is due to the permanent magnets in the rotor, and thus, the reluctance of the path followed by the magnetic flux in the rotor is high compared to the reluctance of the air gap, thus hindering the detection of such faults. As proved in Figures 7 and 8, the discrimination power decreases (both healthy and faulty spectra are almost superimposed) with respect to the operating point corresponding to the nominal conditions, since almost all of the magnetic flux flowing through the stator windings is due to the permanent magnets in the rotor, and thus, the reluctance of the path followed by the magnetic flux in the rotor is high compared to the reluctance of the air gap, thus hindering the detection of such faults.

Motor Working under Low-Load (Low-Saturation) and near d-Position (Current Angle 30 • )
In order to improve the sensitivity of the methods based on the line currents and ZSVC, the motor is analyzed when positioned close to the d axis. In this position, the influence of the permanent magnets can be almost neglected, and the reluctance of the rotor path is still lower than the reluctance of the air gap, thus facilitating the detection of the analyzed faults. In addition, the low current level produces a low magnetic saturation of the rotor segments. This study assumes that the operating conditions are 0.7 A RMS , 150 V RMS , 5000 rev/min, and 30 • current angle. Figure 9 shows the spectral content of the line currents of the analyzed fPMa-SynRM working under low-current low-saturation conditions with a current angle of 30 • , for both healthy and 40% static eccentricity conditions. Appl. Sci. 2017, 7, 565 9 of 14

Motor Working under Low-Load (Low-Saturation) and near d-Position (Current Angle 30°)
In order to improve the sensitivity of the methods based on the line currents and ZSVC, the motor is analyzed when positioned close to the d axis. In this position, the influence of the permanent magnets can be almost neglected, and the reluctance of the rotor path is still lower than the reluctance of the air gap, thus facilitating the detection of the analyzed faults. In addition, the low current level produces a low magnetic saturation of the rotor segments. This study assumes that the operating conditions are 0.7 ARMS, 150 VRMS, 5000 rev/min, and 30° current angle. Figure 9 shows the spectral content of the line currents of the analyzed fPMa-SynRM working under low-current low-saturation conditions with a current angle of 30°, for both healthy and 40% static eccentricity conditions. In this operating point, there are significant differences in the third, ninth, seventeenth, and nineteenth harmonics of the line currents, thus enabling the detection of eccentricity faults. Figure 10 shows the spectral content of the ZSVC when the motor operates under low-current conditions with a current angle of 30°. It shows substantial differences in the third, fifth, and fifteenth harmonics of the ZSVC.

Results Summary
For the sake of better readability, Tables 2 and 3    In this operating point, there are significant differences in the third, ninth, seventeenth, and nineteenth harmonics of the line currents, thus enabling the detection of eccentricity faults. Figure 10 shows the spectral content of the ZSVC when the motor operates under low-current conditions with a current angle of 30 • . It shows substantial differences in the third, fifth, and fifteenth harmonics of the ZSVC.

Motor Working under Low-Load (Low-Saturation) and near d-Position (Current Angle 30°)
In order to improve the sensitivity of the methods based on the line currents and ZSVC, the motor is analyzed when positioned close to the d axis. In this position, the influence of the permanent magnets can be almost neglected, and the reluctance of the rotor path is still lower than the reluctance of the air gap, thus facilitating the detection of the analyzed faults. In addition, the low current level produces a low magnetic saturation of the rotor segments. This study assumes that the operating conditions are 0.7 ARMS, 150 VRMS, 5000 rev/min, and 30° current angle. Figure 9 shows the spectral content of the line currents of the analyzed fPMa-SynRM working under low-current low-saturation conditions with a current angle of 30°, for both healthy and 40% static eccentricity conditions. In this operating point, there are significant differences in the third, ninth, seventeenth, and nineteenth harmonics of the line currents, thus enabling the detection of eccentricity faults. Figure 10 shows the spectral content of the ZSVC when the motor operates under low-current conditions with a current angle of 30°. It shows substantial differences in the third, fifth, and fifteenth harmonics of the ZSVC.

Results Summary
For the sake of better readability, Tables 2 and 3

Results Summary
For the sake of better readability, Tables 2 and 3 summarize the results attained in Sections 5.1-5.3. It is noted that bold values indicate maximum discrimination between healthy and faulty conditions, whereas the grey shading indicates the harmonics and the operating conditions selected to calculate the values of the fault indicators.

The Proposed Fault Indicators
Taking into account the results presented in Section 5, this section proposes an on-line detection using two fault indicators, FI I and FI ZSVC , which are calculated as the difference between the amplitudes of the two harmonics of the stator currents or the ZSVC, respectively. It is assumed that during fault occurrence, the magnitude of the fault indicator is greater than a pre-established threshold value. Figure 11 shows the flow chart of the proposed approach for detecting eccentricity faults. The approach proposed in Figure 11 can be applied for on-line fault detection, since the rotor position, stator currents, and ZSVC can be acquired continuously, and the calculation of the current angle α, the FFT (fast Fourier transform) of the current and ZSVC waveforms, and the fault indicators is very fast. Tables 4 and 5 summarize both the threshold value and the harmonics, which are based on the fault indicators FII and FIZSVC proposed in this section. The values of the fault indicators shown in Tables 4 and 5 have been calculated from the amplitudes of the harmonics presented in Tables 2 and 3.  The approach proposed in Figure 11 can be applied for on-line fault detection, since the rotor position, stator currents, and ZSVC can be acquired continuously, and the calculation of the current angle α, the FFT (fast Fourier transform) of the current and ZSVC waveforms, and the fault indicators is very fast. Tables 4 and 5 summarize both the threshold value and the harmonics, which are based on the fault indicators FI I and FI ZSVC proposed in this section.  The values of the fault indicators shown in Tables 4 and 5 have been calculated from the amplitudes of the harmonics presented in Tables 2 and 3.
It is noted that when using a computer with an Intel core i5-6400T CPU of 2.2 GHz and 16 GB of RAM, the total time required to calculate the i d and i q currents from the phase currents, the current angle α, the FFT of the currents/ZSVC, and the faults indicators is about 3 ms.

Conclusions
Air gap asymmetry is a common fault in electrical machines since it has multiple origins. Eccentricity-related faults generate mechanical stress and electromagnetic asymmetries that worsen machine performance. This paper has analyzed the impact of the operating conditions employed to detect air gap asymmetry faults in fPMa-SynRMs by analyzing the spectral content of the stator currents and the ZSVC, since such faults leave a mark on their respective spectral content. The results presented in this paper clearly show that it is possible to detect eccentricity faults in five-phase fPMa-SynRMs by analyzing both the stator currents and the ZSVC spectra. The results also prove that the effects of eccentricity faults are greatly influenced by the specific operating point of the machine, and the low-current near d-position operating conditions are the most favorable conditions to detect such faults, since the sensitivity of both the stator currents and ZSVC spectral methods is improved. Because of the complex rotor geometry of fPMa-SynRMs, and thus, depending on the path of the magnetic flux in the rotor, the reluctance can increase dramatically, being even greater than that of the air gap, thus hindering the detection of such faults. This work has also proposed specific fault indicators for the on-line detection of eccentricity faults based on the harmonic content of the stator currents and the ZSVC, and their performance has been evaluated, thus proving the usefulness of the proposed approach.
The results summarized in this work may be valuable in designing enhanced fault diagnosis approaches in PMa-SynRMs. It is noted that although the spectral content of the stator currents may be altered by the motor controller, the ZSVC is known to be decoupled from such effects.
Future work will cover the development of methods that can be used to detect, identify, and classify different types of faults in multi-phase fPMa-SynRMs, including eccentricity, demagnetization, and short-circuit, as well as the analysis of more suitable winding configurations for detecting and minimizing the effects of such faults.